Cirrus clouds reflect incoming solar radiation and trap outgoing terrestrial radiation; therefore, accurate estimation of the global energy balance depends upon knowledge of the optical and physical properties of these clouds. Scattering and absorption by cirrus clouds affect measurements made by many satellite-borne and ground based remote sensors. Scattering of ambient light by the cloud, and thermal emissions from the cloud can increase measurement background noise. Multiple scattering processes can adversely affect the divergence of optical beams propagating through these clouds. Determination of the optical thickness and the vertical and horizontal extent of cirrus clouds is necessary to the evaluation of all of these effects. Lidar can be an effective tool for investigating these properties. During the FIRE cirrus IFO in Oct. to Nov. 1986, the High Spectral Resolution Lidar (HSRL) was operated from a rooftop site on the campus of the University of Wisconsin at Madison, Wisconsin. Approximately 124 hours of fall season data were acquired under a variety of cloud optical thickness conditions. Since the IFO, the HSRL data set was expanded by more than 63.5 hours of additional data acquired during all seasons. Measurements are presented for the range in optical thickness and backscattering phase function of the cirrus clouds, as well as contour maps of extinction corrected backscatter cross sections indicating cloud morphology. Color enhanced images of range-time indicator (RTI) displays a variety of cirrus clouds with approximately 30 sec time resolution are presented. The importance of extinction correction on the interpretation of cloud height and structure from lidar observations of optically thick cirrus are demonstrated

Eloranta, Edwin W.

Grund, Christian John

English

NASA Technical Reports Server

Optlcal and Morpholog~cal Properties of Cirrus Clouds Deterrnlned 
by the High Spectral Resolution Lidar During FIRE 
C h r l s t l a  GrunQ and Edwln W. Eloranta 
University of Wisconsin, Department of Meteorology 
1225 W. Dayton St., Madison, WI. 53706 
1. Introduction 
Cirrus clouds reflect incoming solar radiation and trap outgoing terrestrial radiation; therefore, 
accurate estimation of the global energy balance depends upon knowledge of the optical and 
physical properties of these clouds. Scattering and absorption by cirrus clouds affect measurements 
made by many satellite-borne and ground-based remote sensors. Scattering of ambient light by the 
cloud, and thermal emissions from the cloud can increase measurement background noise. Multiple 
scattering processes can adversely affect the divergence of optical beams propagating through these 
clouds. Determination of the optical thickness and the vertical and horizontal extent of cirrus clouds is 
necessary to the evaluation of all of these effects. Lklar can be an effective tool for investigating these 
properties. 
During the FIRE cirrus I F 0  in 0ct.-Nov. 1986, the High Spectral Resolution Lidar (HSRL) was 
operated from a rooftop site (43O 4' 29" N, 89O 24' 26", 347.8 m msl ) on the campus of the University 
of Wisconsin at Madison, Wisconsin. Approximately 124 hours of fall season data were acquired under 
a variety of cloud optical thickness conditions. Since the IFO, the HSRL data set has been expanded 
by more than 63.5 hours of additional data acquired during all seasons. This paper will present 
measurements of the range in optical thickness and backscatter phase function of cirrus clouds, as 
well as contour maps of extinction corrected backscatter cross sections indicating cloud morphology. 
In our talk, we will present color enhanced images of range-time indicator (RTI) displays of a variety 
of cirrus clouds with -30 sec time resolution. We will also demonstrate the importance of extinction 
correction on the interpretation of cloud height and structure from lidar observations of optically thick 
cirrus. 
II. Technlque 
Because the lidar return signal from any range depends on both the backscatter cross section and 
tho 2-way optical depth to that range, simple lidar systems, which make one measurement at each 
range, may not separately measure backscatter and extinction. Accurate knowledge of the extinction 
at one range, and a profile of the range dependence of the backscatter to extinction ratio (backscatter 
phase function), is essential to the determination of extinction from these lidar systems1. The HSRL 
differs from simple lidar systems in that it separates the particulate backscatter component from the 
molecular backscatter component of the lidar return.2 Extinction is directly and unambiguously 
determined from the separated molecular backscatter return and an atmospheric density profile. This 
is possible because the atmospheric density determines the molecular backscatter cross section, 
thereby establishing a known target available at every range. The separation of molecular from 
particulate backscatter is achieved by observing differences in the spectral distribution of the 
scattered energy. The rapid thermal motion of the molecules Doppler-broadens the molecular 
backscatter spectrum. Particulates are more massive than molecules and are thus characterized by 
slower Brownian drift velocities which produce insignificant broadening of the scattered spectrum. 
The HSRL observes the return signal in two channels: a spectrally broad channel encompassing the 
molecular backscatter spectrum, and a spectrally narrow channel centered on the transmitted 
wavelength. With a system calibration3, the 2-channel signals may be inverted to provide separate 
profiles of particulate and molecular scattering. Once the extinction is determined, the separated 
patticutate scattering profile may be directly employed to determine the backscatter phase function. 
111. Data Analysls 
The particulate backscatter cross sections presented in fig.% 1 - 4 were produced from inverted, 
49 
https://ntrs.nasa.gov/search.jsp?R=19910001145 2020-03-19T20:15:11+00:00Z
time averaged particulate and molecular scattering profiles acquired during fixed, vertically-pointing 
HSRL operations. They represent contour maps of the extinction corrected backscatter intensity of 
the cirrus clouds as they evolve in time and drift over the HSRL with the ambient winds. To reduce 
statistical noise, and mitigate the effects of aerosol-molecular channel cross talk, the HSRL in-cloud 
molecular backscatter signal has been obtained according to the following algorithm: 1) regions of 
small particulate-molecular channel cross talk (i.e. regions characterized by background aerosol andlor 
pure Rayleigh backscatter) are identified both above and below the cloud, 2) in these cloud-free 
regions, a least squares fit is produced of the observed molecular signal to the expected profile for a 
pure molecular scattering atmosphere calculated from a density profile, 3) the clear air observed 
signals are replaced with the smooth best fit estimates above and below the cloud, 4) the total cloud 
extinction is determined from the decrease in the best fit molecular signal across the cloud 
determined in step 3, while accounting for the expected decrease in molecular cross section with 
altitude, 5) on the assumption of a constant backscatter phase function and constrained by the optical 
thickness determined in step 4, a Bernoulli4 solution for the extinction distribution within the cloud is 
produced from the inverted particulate backscatter profile, 6) the in-cloud molecular backscatter signal 
is replaced with a smooth estimate calculated from the extinction profile determined in step 5 and the 
known altitude distribution of of the molecular backscatter cross section. In this way, noise is removed 
from the molecular scattering profile, while the distribution of extinction is closely maintained. 
Temporal averaging has been applied to the backscatter cross section profiles used to produce 
fig.'s 1 - 4. Noise considerations are such that 8-15 minute time resolution is possible at night, 
depending upon output power and upon cloud altitude and optical thickness. Daytime temporal 
resolution is somewhat degraded because of an increase in the background noise due to scattered 
sun light. Signal averaging times were chosen so as to lima the errors due to statistical fluctuations to - 
+15% of the average in-cloud backscatter cross section for each profile. The resolution of the profiles 
used to produce fig. 1 is -8 minutes and -12 minutes for fig. 3. Fig. 2 has a time resolution -1 hour, 
and the range resolution has been reduced to 900 meters in order to filter noise from the small 
particulate signals observed during that time period. Operations on Jan. 29-30, 1988 provided 
exceptional data, with 10 minute averaging possible during daylight and nighttime observations, even 
though the measured optical thicknesses occasionally exceeded 2. 
The dashed lines presented in these plots represent a best estimate for an optical mid-cloud 
height. Half the cloud optical thickness is accumulated below this line as determined from the 
Bernoulli solution to the in-cloud extinction. Because the optical thickness of cirrus clouds may be 
generated by a highly irregular vertical distribution of extinction, this optical mid-cloud level could be 
useful in conjunction with (or instead of) cloud top and bottom altitudes in radiative transfer models. 
IV. Dlscusslon 
On examining fig.% 1-4 it is evident that cirrus clouds are produced in a variety of forms with large 
variations in cloud altitude and, thickness. For instance, during the ET0 (10/30/87), we observed a 
-100 m thick single layer cirrus cloud which persisted at 12.5 km for more than 1 hour. In contrast, fig. 
4 (1/29-30188) shows an 8 hour period of repeated, vertically developed cells, imbedded in an 
unbroken cirrus cloud layer having a vertical extent which occasionally exceeded 8 km. 
Fig. 1 shows a contour plot of the backscatter cross section of an isolated cirrus cloud structure 
occurring on 10127186. Assuming no temporal development, and translation of the cloud with the 
ambient wind, the horizontal extent of this feature is estimated to be 48 km. The maximum value for 
the backscatter cross section was observed to be 4.4.1 0-6 m-l  sr-l .The average optical thickness of 
this cloud was .03 k.006, with a bulk backscatter phase function of .028+.005 sr-l. 
Occasionally, background veils of optically thin (sub-visible) cirrus have been observed . Fig. 2 is a 
contour plot of such an event. In the vertical, this 3-5 km thick layer had an average optical thickness of 
.01+.004. It is important to note that the 19 WS wind speeds at 10 km altitude imply a 266 km 
horizontal extent for this veil. One implication of such large scale "thin" cirrus is that remote sensors 
attempting to view horizontally within such layers could encounter optical thicknesses approaching 1 
even though the cloud may not be visually apparent. 
Fig. 3 depicts the backscatter cross section map of a cirrus cloud complex with a wind-drift- 
estimated horizontal extent of -96 km. The maximum observed backscatter cross section was 
determined to be 2.4-1 0-5 m-l  sr-l. Profiles averaged between 540 and 7:40 GMT indicated a mean 
optical thickness of .58+.05 and a bulk backscatter phase function of .047+.007 sr-1. 
50 
Fig. 4 shows an 8 hour segment of the backscatter cross section for a warm frontal cirrus system 
which occurred on 1/29-30/88. The maximum backscatter cross section of 4.3-1 0-5 m-lsr- l  was 
observed near 130 GMT. Twenty minute averaged optical thickness varied between between .081 
and 2.27 (see fig. 5). while the backscatter phase function varied from .031 - .057 s f  (see fig. 6). At 
the time of this writing, error bars had not been established for this data, but they should be 
comparable to previously reported values. It is interesting to note the large and systematic variation in 
backscatter phase function during a period of nearly constant optical thickness occurring between 
18:OO-2O:OO GMT. This implies that a substantial portion ot !he structural information conveyed in fig. 
4 is due to changes in the backscatter phase function and not just modulations of the extinction cross 
section. Thus, caution must be used in the application of simple lidar backscatter profiles to infer cloud 
radiative properties, even in a relative sense. 
Table 1 summarizes the cirrus cloud optical thickness and bulk backscatter phase function 
estimates thus far completed. The mid-cloud optical altitude has been taken as representative for the 
determination of cloud temperature. These measurements represent only the analysed portion of the 
much larger HSRL cirrus cloud data set acquired since October,l986. They were produced from 15 - 
120 minute data averages, and are indicative of the bulk properties across the entire cloud layer. The 
backscatter phase function dependence on mid-cloud temperature reported by Plan and Dilley6 has 
not been observed in the HSRL data set. 
V. Summary 
Since the fall of 1986, we have observed cirrus clouds with backscatter cross sections ranging 
from 1-10-7 - 4.2-10-5 m-lsr-l , optical thicknesses from .001 - 2.3, and exhibiting backscatter phase 
functions in the range of .021 - .061 sr-l. Persistent cirrus cloud layers have been observed with 
vertical thicknesses of -.1 - 8 km. Coherent structural details ranging from 10s of meters and 
exceeding 250 km have been recorded. However, significant improvements in HSRL measurement 
statistics will be necessary to produce optical thickness and backscatter phase function 
measurements on lime scales of less than 10 minutes, to reveal details of internal cloud optical 
properties, or to produce real time volume scans. 
Fortunately, we are in the process of upgrading the system with a more powerful and spectrally 
stable laser which will decrease our time average requirements by a factor of -40. This laser should 
also provide additional reductions in the aerosol-molecular channel cross talk terms, improving 
detailed analysis of backscatter phase function and extinction within cirrus clouds. It is possible that 
the HSRL will be operational with this new set of capabilities by the July 1988 meeting date. 
This research has been supported under ARO grant DAAG29-84-K-0069 and ONR contract 
N00014-85-K-0581. 
References 
1. F. Fernald, B.M. Herman, J.A. Reagan, Determination of aerosol Height Distributions b y  Lidar, 
2. C.J. Grund. -us C i r a i  -, 
U.Wisconsin-Madison, (1987). 
3. C.J. Grund and E.W. Eloranta, Interpretation of the Optical and Morphological Properties of Cirrus 
4. J.A.Weinman, The Derivation of Atmospheric Extinction Profiles and Wind Speed Over the Ocean 
5. Platt, C.M.R. and A.C.Dilley, Determination of Cirrus Particle Single-Scattering Phase Function 
J.Appl.Meteor. 11, 482, (1972). 
Ph.D. Thesis, 
Clouds from Lidar Measurements, elsewhere in this volume. 
from a Satellite Borne Lidar, Submitted to App.Opt., (1988). 
from Lidar and Solar Radiometric Data, App.0pt. 23, 380, (1984). 
51 
Backscatter Cross Sectlon (aO-'m-' or-' > 
e.0 
0 v o  
%oO 1 1  m o o  ..em 
HIW. OUT io/nr/es 
Fig. 1 Conlour plot showing the particulate backscaller cross seclion [ l o 7  
rn-lsr-1) dislrtbulion within a cirrus doud f-1. The dashed line indicates 
me opUcal midcloud heghte - -. see lexl). The average oplical IhICkness d 
lhis cloud was .03 wilh a bulk backscaller phase lunclion 01.028 sr1. 
Backscatter Cross Section (IO - O m - '  m r - '  1 
IS.0, 
1.0 
8.m r.m s.m 8.00  7.0 0.00 now. GUT OD 10/2e/ee 
FIg. 2 Background veil of enhanced particulate backscaller may persist at 
cirrus cloud 811itudes even when cirrus are no1 apparent. The range 
resolution has been reduced lo 900 rn to improve Ihe Msa slatisltcs ot lhis 
k w  backscaner data. Contour units are 10.8 rn-lsr-1. 
Backscatter Cross Sectlon (IO -' m-' or-' B 
1s. . . . . . . . . . . . . . - - 
. - - I  
6 . 0  '1.00 8.m L m 
no- o m  OP io/ne/ea 
Flp. 3 Backscatter aoss secllon (--J and midcloud optical helghl(- - -) 01 a 
arws doud complex. Average oplkal thickness 01 this s slern was lound lo 
be .sB wllh a bulk backscatter phase IuncUon 01 .a(? err. Conlow unils are 
10-7m-lwl. 
4 0 '  . . a .  . ' ' .  . . ' 
" 1  
028% om 
021*OW 
013: w(I 
023f we 
mLt010 
M l t O l l  
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024*  W I  
0231 w? 
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m2fo1a 
02.rO13 
mk OII 
0211014 
m 1 t o l 5  
0451 012 
Mlt 001 
m4 
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OB 
057 
(u1 
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035 
me ou 
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MI 
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MI 
m8 
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049 
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OM 
ma 
mi 
ma 
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5 4 3  I$ 
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4 1 2  15 
411 15 
4.0 4 
.si a Y 
4 1 s  Is 
J.0 45 
4 8 5  4 
J.3 45 
4 8 s  4 
4 7 2  la 
.2ea A 
a s  m 
5 3 9  10 
d 7 8  20 
a s 0  a 
a e e  a 
4 1 8  20 
JI1 A 
4 0 0  a 
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4 7 9  m 
310 20 
. u 7  20 
4 a 7  10 
4 2 1  I 2  
a a 7  10 
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4 0 0  .le* 10 A 
52 
13.0 
12.0 
11.0 
3- si 
W A O a O  
a3 3 8.0 
ti 
7.0 
6.0 
5.0 
4.0 
Backscatter C r o s s  Section (io -s m-' 8 r - l  ) 
2.1 . - -  . . . .  - - . - - - - .  
2.2 
2.0 
I .e 
1.8 
1.S 
1.2 
1 .o 
.e 
18100 19100 20100 21100 22100 23t00 OOmOO 01100 02800 
Hours GMT on 1/28 - 1/30/88 
Flg. 4 (top) Backscatter crdss section (-) and mid-cloud optical height (- - -) of a 
cirrus cloud shield preceding a warm front. Notice the series of repeated cells of 
enhanced backscatter. Modulations of the mid-cloud height (1-2 km) are closely tied to 
the cell patterns. Fig. 5 (middle) Optical thickness record for 1129-30/88 (20 minute 
independent averages). Fig. 6 (bottom) Backscatter phase function record for 1 /29- 
30/88 (20 minute Independent averages). Note the large systematic change in the 
backscatter phase function during the first 2 hours of the data set. This change 
occurred even though the average optical thickness remained constant. indicating that 
much of the structural information conveyed in fig. 4 was not simply produced by 
modulation of the extinction. Thus, caution must be used In the application of simple 
lidar backscatter profiles to infer cloud radiative properties, even in a relative sense. 
53 


Optical and morphological properties of Cirrus clouds determined by the high spectral resolution lidar during FIRE

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